/* atof_generic.c - turn a string of digits into a Flonum
   Copyright (C) 1987 Free Software Foundation, Inc.

This file is part of GAS, the GNU Assembler.

GAS is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 1, or (at your option)
any later version.

GAS is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
GNU General Public License for more details.

You should have received a copy of the GNU General Public License
along with GAS; see the file COPYING.  If not, write to
the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.  */

#include <stdint.h>
#include <ctype.h>
#include <stdlib.h>
#include <string.h>
#include "flonum.h"

#define	FALSE (0)
#define TRUE  (1)

/***********************************************************************\
*									*
*	Given a string of decimal digits , with optional decimal	*
*	mark and optional decimal exponent (place value) of the		*
*	lowest_order decimal digit: produce a floating point		*
*	number. The number is 'generic' floating point: our		*
*	caller will encode it for a specific machine architecture.	*
*									*
*	Assumptions							*
*		uses base (radix) 2					*
*		this machine uses 2's complement binary integers	*
*		target flonums use "      "         "       "		*
*		target flonums exponents fit in a long int		*
*									*
\***********************************************************************/

/*

			Syntax:

<flonum>		::=	<optional-sign> <decimal-number> <optional-exponent>
<optional-sign>		::=	'+' | '-' | {empty}
<decimal-number>	::=	  <integer>
				| <integer> <radix-character> 
				| <integer> <radix-character> <integer> 
				|	    <radix-character> <integer>
<optional-exponent>	::=	{empty} | <exponent-character> <optional-sign> <integer> 
<integer>		::=	<digit> | <digit> <integer>
<digit>			::=	'0' | '1' | '2' | '3' | '4' | '5' | '6' | '7' | '8' | '9'
<exponent-character>	::=	{one character from "string_of_decimal_exponent_marks"}
<radix-character>	::=	{one character from "string_of_decimal_marks"}

*/

/* 0 if OK */
int
atof_generic (
char **address_of_string_pointer, /* return pointer to just AFTER number read */
const char *string_of_decimal_marks,    /* at most one per number */
const char *string_of_decimal_exponent_marks,
FLONUM_TYPE *address_of_generic_floating_point_number)
{

  int			return_value; /* 0 means OK. */
  char *		first_digit;
  /* char *		last_digit; JF unused */
  int			number_of_digits_before_decimal;
  int			number_of_digits_after_decimal;
  int32_t		decimal_exponent;
  int			number_of_digits_available;
  char			digits_sign_char;

  {
    /*
     * Scan the input string, abstracting (1)digits (2)decimal mark (3) exponent.
     * It would be simpler to modify the string, but we don't; just to be nice
     * to caller.
     * We need to know how many digits we have, so we can allocate space for
     * the digits' value.
     */

    char *		p;
    char		c;
    int			seen_significant_digit;

    first_digit = * address_of_string_pointer;
    c= *first_digit;
    if (c=='-' || c=='+')
      {
	digits_sign_char = c;
        first_digit ++;
      }
    else
	digits_sign_char = '+';

    if(   (first_digit[0]=='n' || first_digit[0]=='N')
       && (first_digit[1]=='a' || first_digit[1]=='A')
       && (first_digit[2]=='n' || first_digit[2]=='N')) {
      address_of_generic_floating_point_number->sign=0;
      address_of_generic_floating_point_number->exponent=0;
      address_of_generic_floating_point_number->leader=address_of_generic_floating_point_number->low;
      (*address_of_string_pointer)=first_digit+3;
      return 0;
    }
    if(   (first_digit[0]=='i' || first_digit[0]=='I') 
       && (first_digit[1]=='n' || first_digit[1]=='N')
       && (first_digit[2]=='f' || first_digit[2]=='F')) {
      address_of_generic_floating_point_number->sign= digits_sign_char=='+' ? 'P' : 'N';
      address_of_generic_floating_point_number->exponent=0;
      address_of_generic_floating_point_number->leader=address_of_generic_floating_point_number->low;
      if(   (first_digit[3]=='i' || first_digit[3]=='I')
         && (first_digit[4]=='n' || first_digit[4]=='N')
	 && (first_digit[5]=='i' || first_digit[5]=='I')
	 && (first_digit[6]=='t' || first_digit[6]=='T')
	 && (first_digit[7]=='y' || first_digit[7]=='Y'))
	  (*address_of_string_pointer)=first_digit+8;
      else
	  (*address_of_string_pointer)=first_digit+3;
      return 0;
    }

    number_of_digits_before_decimal = 0;
    number_of_digits_after_decimal = 0;
    decimal_exponent = 0;
    seen_significant_digit = FALSE;
    for (p = first_digit;
	 (c = * p)
	 && (!c || ! strchr(string_of_decimal_marks,          c) )
	 && (!c || ! strchr(string_of_decimal_exponent_marks, c) );
	 p ++)
      {
	if (isdigit(c))
	  {
	    if (seen_significant_digit || c > '0')
	      {
		number_of_digits_before_decimal ++;
		seen_significant_digit = TRUE;
	      }
	    else
	      {
	        first_digit++;
	      }
	  }
	else
	  {
	    break;		/* p -> char after pre-decimal digits. */
	  }
      }				/* For each digit before decimal mark. */
    if (c && strchr(string_of_decimal_marks, c))
      {
	for (p ++;
	     (c = * p)
	     && (!c || ! strchr(string_of_decimal_exponent_marks, c) );
	     p ++)
	  {
	    if (isdigit(c))
	      {
		number_of_digits_after_decimal ++; /* This may be retracted below. */
		if (/* seen_significant_digit || */ c > '0')
		  {
		    seen_significant_digit = TRUE;
		  }
	      }
	    else
	      {
		if ( ! seen_significant_digit)
		  {
		    number_of_digits_after_decimal = 0;
		  }
		break;
	      }
	  }			/* For each digit after decimal mark. */
      }
      while(number_of_digits_after_decimal && first_digit[number_of_digits_before_decimal+number_of_digits_after_decimal]=='0')
	--number_of_digits_after_decimal;
/*    last_digit = p; JF unused */
    
    if (c && strchr(string_of_decimal_exponent_marks, c) )
      {
	char		digits_exponent_sign_char;
	
	c = * ++ p;
	if (c && strchr("+-",c))
	  {
	    digits_exponent_sign_char = c;
	    c = * ++ p;
	  }
	else
	  {
	    digits_exponent_sign_char = '+';
	  }
	for (;
	     (c);
	     c = * ++ p)
	  {
	    if (isdigit(c))
	      {
		decimal_exponent = decimal_exponent * 10 + c - '0';
		/*
		 * BUG! If we overflow here, we lose!
		 */
	      }
	    else
	      {
		break;
	      }
	  }
	if (digits_exponent_sign_char == '-')
	  {
	    decimal_exponent = - decimal_exponent;
	  }
      }
    * address_of_string_pointer = p;
  }

  number_of_digits_available =
    number_of_digits_before_decimal
      + number_of_digits_after_decimal;
  return_value = 0;
  if (number_of_digits_available == 0)
    {
      address_of_generic_floating_point_number -> exponent = 0;	/* Not strictly necessary */
      address_of_generic_floating_point_number -> leader
	= -1 + address_of_generic_floating_point_number -> low;
      address_of_generic_floating_point_number -> sign = digits_sign_char;
      /* We have just concocted (+/-)0.0E0 */
    }
  else
    {
      LITTLENUM_TYPE *	digits_binary_low;
      int		precision;
      int		maximum_useful_digits;
      int		number_of_digits_to_use;
      int		more_than_enough_bits_for_digits;
      int		more_than_enough_littlenums_for_digits;
      int		size_of_digits_in_littlenums;
      int		size_of_digits_in_chars;
      FLONUM_TYPE	power_of_10_flonum;
      FLONUM_TYPE	digits_flonum;


      precision = (address_of_generic_floating_point_number -> high
		   - address_of_generic_floating_point_number -> low
		   + 1
		   );		/* Number of destination littlenums. */
				/* Includes guard bits (two littlenums worth) */
      maximum_useful_digits = (  ((double) (precision - 2))
			       * ((double) (LITTLENUM_NUMBER_OF_BITS))
			       / (LOG_TO_BASE_2_OF_10)
			       )
	+ 2;			/* 2 :: guard digits. */
      if (number_of_digits_available > maximum_useful_digits)
	{
	  number_of_digits_to_use = maximum_useful_digits;
	}
      else
	{
	  number_of_digits_to_use = number_of_digits_available;
	}
      decimal_exponent += number_of_digits_before_decimal - number_of_digits_to_use;

      more_than_enough_bits_for_digits
	= ((((double)number_of_digits_to_use) * LOG_TO_BASE_2_OF_10) + 1);
      more_than_enough_littlenums_for_digits
	= (  more_than_enough_bits_for_digits
	   / LITTLENUM_NUMBER_OF_BITS
	   )
	  + 2;
      
      /*
       * Compute (digits) part. In "12.34E56" this is the "1234" part.
       * Arithmetic is exact here. If no digits are supplied then
       * this part is a 0 valued binary integer.
       * Allocate room to build up the binary number as littlenums.
       * We want this memory to disappear when we leave this function.
       * Assume no alignment problems => (room for n objects) ==
       * n * (room for 1 object).
       */
      
      size_of_digits_in_littlenums = more_than_enough_littlenums_for_digits;
      size_of_digits_in_chars = size_of_digits_in_littlenums
	* sizeof( LITTLENUM_TYPE );
      digits_binary_low = (LITTLENUM_TYPE *)
	alloca (size_of_digits_in_chars);
      memset((char *)digits_binary_low, '\0', size_of_digits_in_chars);

      /* Digits_binary_low[] is allocated and zeroed. */
      
      {
	/*
	 * Parse the decimal digits as if * digits_low was in the units position.
	 * Emit a binary number into digits_binary_low[].
	 *
	 * Use a large-precision version of:
	 * (((1st-digit) * 10 + 2nd-digit) * 10 + 3rd-digit ...) * 10 + last-digit
	 */

	char *		p;
	char		c;
	int		count;	/* Number of useful digits left to scan. */

	for (p = first_digit, count = number_of_digits_to_use;
	     count;
	     p ++,  -- count)
	  {
	    c = * p;
	    if (isdigit(c))
	      {
		/*
		 * Multiply by 10. Assume can never overflow.
		 * Add this digit to digits_binary_low[].
		 */

		int32_t	carry;
		LITTLENUM_TYPE *	littlenum_pointer;
		LITTLENUM_TYPE *	littlenum_limit;

		littlenum_limit
		  =     digits_binary_low
		    +   more_than_enough_littlenums_for_digits
		      - 1;
		carry = c - '0';	/* char -> binary */
		for (littlenum_pointer = digits_binary_low;
		     littlenum_pointer <= littlenum_limit;
		     littlenum_pointer ++)
		  {
		    int32_t	work;
		    
		    work = carry + 10 * (int32_t)(*littlenum_pointer);
		    * littlenum_pointer = work & LITTLENUM_MASK;
		    carry = work >> LITTLENUM_NUMBER_OF_BITS;
		  }
		if (carry != 0)
		  {
		    /*
		     * We have a GROSS internal error.
		     * This should never happen.
		     */
		    abort();	/* RMS prefers abort() to any message. */
		  }
	      }
	    else
	      {
		++ count;	/* '.' doesn't alter digits used count. */
	      }		/* if valid digit */
	  }			/* for each digit */
      }

      /*
       * Digits_binary_low[] properly encodes the value of the digits.
       * Forget about any high-order littlenums that are 0.
       */
      while (digits_binary_low [size_of_digits_in_littlenums - 1] == 0
	     && size_of_digits_in_littlenums >= 2)
	  size_of_digits_in_littlenums --;

      digits_flonum . low	= digits_binary_low;
      digits_flonum . high	= digits_binary_low + size_of_digits_in_littlenums - 1;
      digits_flonum . leader	= digits_flonum . high;
      digits_flonum . exponent	= 0;
      /*
       * The value of digits_flonum . sign should not be important.
       * We have already decided the output's sign.
       * We trust that the sign won't influence the other parts of the number!
       * So we give it a value for these reasons:
       * (1) courtesy to humans reading/debugging
       *     these numbers so they don't get excited about strange values
       * (2) in future there may be more meaning attached to sign,
       *     and what was
       *     harmless noise may become disruptive, ill-conditioned (or worse)
       *     input.
       */
      digits_flonum . sign	= '+';

      {
	/*
	 * Compute the mantssa (& exponent) of the power of 10.
	 * If sucessful, then multiply the power of 10 by the digits
	 * giving return_binary_mantissa and return_binary_exponent.
	 */

	LITTLENUM_TYPE *power_binary_low;
	int		decimal_exponent_is_negative;
				/* This refers to the "-56" in "12.34E-56". */
				/* FALSE: decimal_exponent is positive (or 0) */
				/* TRUE:  decimal_exponent is negative */
	FLONUM_TYPE	temporary_flonum;
	LITTLENUM_TYPE *temporary_binary_low;
	int		size_of_power_in_littlenums;
	int		size_of_power_in_chars;

	size_of_power_in_littlenums = precision;
/* Precision has a built-in fudge factor so we get a few guard bits. */


	decimal_exponent_is_negative = decimal_exponent < 0;
	if (decimal_exponent_is_negative)
	  {
	    decimal_exponent = - decimal_exponent;
	  }
	/* From now on: the decimal exponent is > 0. Its sign is seperate. */
	
	size_of_power_in_chars
	  =   size_of_power_in_littlenums
	    * sizeof( LITTLENUM_TYPE ) + 2;
	power_binary_low = (LITTLENUM_TYPE *) alloca ( size_of_power_in_chars );
	temporary_binary_low = (LITTLENUM_TYPE *) alloca ( size_of_power_in_chars );
	memset((char *)power_binary_low, '\0', size_of_power_in_chars);
	* power_binary_low = 1;
	power_of_10_flonum . exponent	= 0;
	power_of_10_flonum . low	= power_binary_low;
	power_of_10_flonum . leader	= power_binary_low;
	power_of_10_flonum . high	= power_binary_low	+ size_of_power_in_littlenums - 1;
	power_of_10_flonum . sign	= '+';
	temporary_flonum . low	= temporary_binary_low;
	temporary_flonum . high	= temporary_binary_low		+ size_of_power_in_littlenums - 1;
	/*
	 * (power) == 1.
	 * Space for temporary_flonum allocated.
	 */
	
	/*
	 * ...
	 *
	 * WHILE	more bits
	 * DO	find next bit (with place value)
	 *	multiply into power mantissa
	 * OD
	 */
	{
	  int		place_number_limit;
				/* Any 10^(2^n) whose "n" exceeds this */
				/* value will fall off the end of */
				/* flonum_XXXX_powers_of_ten[]. */
	  int		place_number;
	  const const_FLONUM_TYPE * multiplicand; /* -> 10^(2^n) */

	  place_number_limit = table_size_of_flonum_powers_of_ten;
	  multiplicand
	    = (  decimal_exponent_is_negative
	       ? flonum_negative_powers_of_ten
	       : flonum_positive_powers_of_ten);
	  for (place_number = 1;	/* Place value of this bit of exponent. */
	       decimal_exponent;	/* Quit when no more 1 bits in exponent. */
	       decimal_exponent >>= 1
	       , place_number ++)
	    {
	      if (decimal_exponent & 1)
		{
		  if (place_number > place_number_limit)
		    {
		      /*
		       * The decimal exponent has a magnitude so great that
		       * our tables can't help us fragment it.  Although this
		       * routine is in error because it can't imagine a
		       * number that big, signal an error as if it is the
		       * user's fault for presenting such a big number.
		       */
		      return_value = ERROR_EXPONENT_OVERFLOW;
		      /*
		       * quit out of loop gracefully
		       */
		      decimal_exponent = 0;
		    }
		  else
		    {
#ifdef TRACE
printf("before multiply, place_number = %d., power_of_10_flonum:\n", place_number);
flonum_print( & power_of_10_flonum );
(void)putchar('\n');
#endif
		      flonum_multip ((const_FLONUM_TYPE *)multiplicand + place_number, & power_of_10_flonum, & temporary_flonum);
		      flonum_copy (& temporary_flonum, & power_of_10_flonum);
		    }		/* If this bit of decimal_exponent was computable.*/
		}			/* If this bit of decimal_exponent was set. */
	    }			/* For each bit of binary representation of exponent */
#ifdef TRACE
printf( " after computing power_of_10_flonum: " );
flonum_print( & power_of_10_flonum );
(void)putchar('\n');
#endif
	}

      }

      /*
	   * power_of_10_flonum is power of ten in binary (mantissa) , (exponent).
	   * It may be the number 1, in which case we don't NEED to multiply.
	   *
	   * Multiply (decimal digits) by power_of_10_flonum.
       */

      flonum_multip ((const_FLONUM_TYPE *)&power_of_10_flonum, & digits_flonum, address_of_generic_floating_point_number);
      /* Assert sign of the number we made is '+'. */
      address_of_generic_floating_point_number -> sign = digits_sign_char;

    }				/* If we had any significant digits. */
  return (return_value);
}				/* atof_generic () */

/* end: atof_generic.c */
